An optical pulse-width modifier structure includes a first diffraction grating and an optically unpowered reversing mirror. An optical path extends between the first diffraction grating and the optically unpowered reversing mirror. A second diffraction grating lies on the optical path between the first diffraction grating and the optically unpowered mirror. A set of optically powered mirrors lies on the optical path between the first diffraction grating and the second diffraction grating. The diffraction gratings and mirrors are positioned such that an input light beam is diffracted from the first diffraction grating, reflected from each of the set of optically powered mirrors, diffracted from the second diffraction grating, reflected from the optically unpowered reversing mirror back to the second diffraction grating, diffracted from the second diffraction grating, reflected from each of the set of optically powered mirrors, and diffracted from the first diffraction grating as an output light beam. The present approach produces a differential path length as a function of wavelength.
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1. An optical pulse-width modifier structure, comprising:
a first diffraction grating;
an optically unpowered reversing mirror, wherein an optical path extends between the first diffraction grating and the optically unpowered reversing mirror;
a second diffraction grating lying on the optical path between the first diffraction grating and the optically unpowered reversing mirror; and
a set of optical powered mirrors lying on the optical path between the first diffraction grating and the second diffraction grating,
wherein the diffraction gratings and mirrors are positioned such that an input light beam in order is diffracted from the first diffraction grating, reflected from each of the set of optically powered mirrors, diffracted from the second diffraction grating, reflected from the optically unpowered reversing mirror back to the second diffraction grating, diffracted from the second diffraction grating, reflected from each of the set of optically powered mirrors, and diffracted from the first diffraction grating as an output light beam.
17. An optical pulse-width modifier structure, comprising:
a first diffraction grating;
an optically unpowered reversing mirror, wherein an optical path extends between the first diffraction grating and the optically unpowered reversing roof mirror;
a second diffraction grating lying on the optical path between the first diffraction grating and the optically unpowered reversing roof mirror; and
a set of four optical powered mirrors lying on the optical path between the first diffraction grating and the second diffraction grating, wherein the set of optically powered mirrors has a first pupil at the first diffraction grating and a second pupil at the second diffraction grating, and
wherein the diffraction gratings and mirrors are positioned such that an input light beam in order is diffracted from the first diffraction grating, reflected from each of the set of optically powered mirrors, diffracted from the second diffraction grating, reflected from the optically unpowered reversing roof mirror back to the second diffraction grating, diffracted from the second diffraction grating, reflected from each of the set of optically powered mirrors, and diffracted from the first diffraction grating as an output light beam, and wherein the input light beam is spatially separated from the output light beam.
2. The optical pulse-width modifier structure of
3. The optical pulse-width modifier structure of
4. The optical pulse-width modifier structure of
5. The optical pulse-width modifier structure of
6. The optical pulse-width modifier structure of
7. The optical pulse-width modifier structure of
8. The optical pulse-width modifier structure of
an optically unpowered fold mirror positioned to reflect the input light beam to the first diffraction grating.
9. The optical pulse-width modifier structure of
a positional translator having
a first support upon which the first diffraction grating is mounted,
a second support upon which the second diffraction grating and the optically unpowered reversing mirror are mounted, and
a translator drive that moves the first support and the second support toward or away from the set of optically powered mirrors in a coordinated fashion.
10. The optical pulse-width modifier structure of
11. The optical pulse-width modifier structure of
12. The optical pulse-width modifier structure of
13. The optical pulse-width modifier structure of
an optically unpowered fold mirror positioned to reflect the input light beam to the first diffraction grating.
14. The optical pulse-width modifier structure of
a positional translator having
a first support upon which the first diffraction grating is mounted,
a second support upon which the second diffraction grating and the optically unpowered reversing roof mirror are mounted, and
a translator drive that moves the first support and the second support toward or away from the set of optically powered mirrors in a coordinated fashion.
15. The optical pulse-width modifier structure of
16. The optical pulse-width modifier structure of
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This invention relates to a device that temporally broadens or compresses short-duration light pulses and, more particularly, to a two-pass pulse-width modifier structure with intermediate powered mirrors positioned between diffraction gratings.
Very short-duration, high-power laser pulses are needed for some applications. Such pulses may have a duration in the tens of femtoseconds. However, it may be risky to attempt to amplify such short-duration pulses, because the gain medium may be damaged due to the high peak field and energy densities of the short-duration pulse.
One strategy to amplify short-duration optical pulses is to broaden (i.e., expand) the pulse to a longer duration, for example in the picosecond range. The amplification is performed on the longer-duration pulse, which has a lower energy density than the shorter-duration pulse. Because of the lower energy density of the longer-duration pulse, there is less likelihood of damage to the gain medium of the amplifier. The amplified pulse is then compressed back to the required shorter duration, for example in the tens of femtoseconds range.
The implementation of this amplification strategy requires optical transformations of the light pulse using appropriate hardware. A limiting factor on this amplification strategy is aberrations of various types introduced into the light pulse by the pulse broadening and pulse compression hardware. The aberrations have the net effect of lengthening the minimum pulse duration or, stated alternatively, of placing a limit on the minimum duration of the amplified light pulse. That is, the temporally broadened, amplified, and then temporally compressed light pulse is necessarily longer in time than the original unamplified light pulse.
There is a need for an improved approach to broadening and/or compressing short-duration light pulses, which avoids the limitations placed on the temporal compression by aberration effects. The present invention fulfills this need, and further provides related advantages.
The present approach provides an optical pulse-width modifier structure that minimizes or eliminates common aberrations that otherwise limit the ability to compress light pulses. The input and output light beams may be spatially separated, so that it is easy to access the output light beam separately from the input light beam. The structure is continuously adjustable to vary the amount of temporal broadening or compression of the light pulse, so that a wide range of continuously variable broadening and compression values may be selected. The apparatus is also more compact than alternative approaches.
In accordance with the invention, an optical pulse-width modifier structure comprises a first diffraction grating and an optically unpowered reversing mirror. An optical path extends between the first diffraction grating and the optically unpowered reversing mirror. The optical pulse-width modifier structure further includes a second diffraction grating lying on the optical path between the first diffraction grating and the optically unpowered reversing mirror, and a set of optically powered mirrors lying on the optical path between the first diffraction grating and the second diffraction grating. The diffraction gratings and mirrors are positioned such that an input light beam is diffracted from the first diffraction grating, reflected from each of the set of optically powered mirrors, diffracted from the second diffraction grating, reflected from the optically unpowered reversing mirror back to the second diffraction grating, diffracted from the second diffraction grating, reflected from each of the set of optically powered mirrors, and diffracted from the first diffraction grating as an output light beam.
In the preferred approach, the set of optically powered mirrors has a first pupil at the first diffraction grating and a second pupil at the second diffraction grating. The set of optically powered mirrors comprises four optically powered mirrors, most preferably having optical powers in order of positive, negative, negative, and positive.
Preferably, the optically unpowered reversing mirror is a roof mirror or its equivalent. This provides one approach whereby the input light beam is spatially separated from the output light beam.
There is optionally an optically unpowered fold mirror positioned to reflect the input light beam to the first diffraction grating, and the output light beam received from the first diffraction grating.
Desirably, the optical pulse-width modifier structure further includes a positional translator drive having a first support upon which the first diffraction grating (and the optically unpowered fold mirror, where provided) is mounted, and a second support upon which the second diffraction grating and the optically unpowered reversing mirror are mounted. The first support and the second support move toward or away from the set of optically powered mirrors in a coordinated fashion. This movement alters the optical path length difference for light of different wavelengths. For example, there may be no optical path length difference for light of different wavelengths along the optical path between the first diffraction grating and the second diffraction grating. There may instead be an optical path length difference for light of different wavelengths along the optical path between the first diffraction grating and the second diffraction grating.
In a particularly preferred embodiment, an optical pulse-width modifier structure comprises a first diffraction grating, and an optically unpowered reversing roof mirror. An optical path extends between the first diffraction grating and the optically unpowered reversing roof mirror. A second diffraction grating lies on the optical path between the first diffraction grating and the optically unpowered reversing roof mirror. A set of four optically powered mirrors lies on the optical path between the first diffraction grating and the second diffraction grating. The set of optically powered mirrors has a first pupil at the first diffraction grating and a second pupil at the second diffraction grating. The diffraction gratings and mirrors are positioned such that an input light beam is diffracted from the first diffraction grating, reflected from each of the set of optically powered mirrors, diffracted from the second diffraction grating, reflected from the optically unpowered reversing roof mirror back to the second diffraction grating, diffracted from the second diffraction grating, reflected from each of the set of optically powered mirrors, and diffracted from the first diffraction grating as an output light beam. With this approach, the input light beam is spatially separated from the output light beam. Other compatible features discussed herein may be used with this embodiment.
The present apparatus may be used either to broaden a short pulse or to compress a long pulse. Pulse broadening is accomplished in either of two ways: first, by adding relatively more optical path to the short wavelength of the pulse, creating a pulse where long wavelength leads the pulse; or, second, by adding relatively more optical path length to the long wavelength of the pulse, creating a pulse where the short wavelength leads the pulse. Pulse compression is performed either, where the short wavelength leads the pulse, by adding relatively more optical path length to the short wavelength; or, where the long wavelength leads the pulse, by adding relatively more optical path length to the long wavelength.
The present approach permits continuously adjustable optical pulse-width modification while minimizing or eliminating the aberrations that otherwise limit the ability to compress light pulses. With the preferred embodiment using the optically unpowered reversing roof mirror or its equivalent, the input and output light beams are spatially separated, providing easy access to the input and output light beams without using a beam splitter or the like. A wide range of continuously variable broadening and compression values may be selected because of the continuously adjustable positional translator drive. This apparatus is compact in size and relatively light in weight.
Other possible techniques for altering the spatial/temporal characteristics of a laser pulse generally involve three steps: first, some form of spectral/spatial separation of the pulse; second, selective introduction of optical path length as a function of wavelength; and third, spectral/spatial recombination of the pulse. Diffraction gratings and prisms could be used in the first step, although a grating would be preferred due to the high, angular dispersion and linearity of the dispersion. Grating pairs, imaging between grating pairs using refractive optics, and double pass optical systems could be used for the second and third steps, but these approaches are not well corrected for monochromatic and polychromatic aberrations. The presence of either kind of aberration is a serious impediment to the orderly creation of a broadened pulse or the creation of a narrowly compressed pulse from a broader pulse. Additionally, alternative techniques fail to provide for spatial separation of the input and output beams for appropriate access to both beams, and do not permit both broadening and compression of the optical pulse with a single apparatus.
Other features and advantages of the present invention will be apparent from the following more detailed description of the preferred embodiment, taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention. The scope of the invention is not, however, limited to this preferred embodiment.
A set 30 of four optically powered mirrors lies on the optical path 26 between the first diffraction grating 22 and the second diffraction grating 28. The set of mirrors is shown as a single block in
The set 30 must be made of mirrors. The set 30 may not be made of refractive optical elements such as lenses, because the optical properties of lenses vary according to the wavelength of the light passing through them. The set 30 of optically powered mirrors 32, 34, 36, and 38 is afocal. The set 30 of optically powered mirrors 32, 34, 36, and 38 has a first pupil 40 at the first diffraction grating 22 and a second pupil 42 at the second diffraction grating 28.
The optical pulse-width modifier structure 20 optionally includes an optically unpowered fold mirror 44 positioned to reflect an input light beam 46 to the first diffraction grating 22, and to reflect an output light beam 48 from the first diffraction grating 22.
The diffraction gratings 22 and 28, and mirrors 24, 32, 34, 36, 38 and 44 (where used) are positioned such that the input light beam 46 is reflected from the optically unpowered fold mirror 44 (where used), diffracted from the first diffraction grating 22, reflected from each of the set 30 of optically powered mirrors 32, 34, 36, and 38 in that order, and diffracted from the second diffraction grating 28. The optical path 26 is then reflected from the optically unpowered reversing mirror 24 back through this same set of optical components in the opposite order. That is, the optical path 26 travels from the optically unpowered reversing mirror 24 back to the second diffraction grating 28, diffracted from the second diffraction grating 28, reflected from each of the set 30 of optically powered mirrors 38, 36, 34, and 32 in that order, diffracted from the first diffraction grating 22, and reflected from the optically unpowered fold mirror 44 (where used) as the output light beam 48.
The optically unpowered mirror 24 is termed a “reversing” mirror because it reverses the direction of the optical path 26 back through the other elements of the optical pulse-width modifier structure 20. Where the optically unpowered reversing mirror 24 is a flat mirror, the outgoing optical path 26b is coincident with the incoming optical path 26a. The result is that the output light beam 48 is coincident with the input light beam 46. In a more preferred embodiment, the optically unpowered mirror 24 is a roof mirror or its equivalent that transversely displaces the outgoing optical path 26b from the incoming optical path 26a. The result is that the output light beam 48 is transversely spatially separated and displaced from the input light beam 46, as may be seen in the perspective view of
The degree of temporal pulse broadening (i.e., expansion) or compression of a laser or other light pulse is determined by the distance, measured along the optical path 26, between the first diffraction grating 22 and the second diffraction grating 28. For some applications, this distance may be fixed. More generally and preferably, however, the distance between the diffraction gratings 22 and 28 is adjustable. To allow this distance to be controllably adjusted, the optical pulse-width modifier structure 20 is preferably provided with a positional translator having a first support 50 upon which the first diffraction grating 22 and the optically unpowered fold mirror 44 (where used) are mounted, and a second support 52 upon which the second diffraction grating 28 and the optically unpowered reversing mirror 24 are mounted.
The positional translator drive 54 moves the first support 50 and the second support 52 toward or away from the set 30 of optically powered mirrors 32, 34, 36, and 38 in a coordinated, symmetric fashion. That is, the translator drive 54 includes a support drive 56 that moves the first support 50 to the left by the same amount that it moves the second support 52 to the right, to maintain the symmetry of the structure about the set 30 of optically powered mirrors. This maintenance of symmetry is illustrated in
In
In
An optical pulse-width modifier structure 20 has been designed according to the preferred structure illustrated in
In considering temporal pulse broadening and compression of a laser pulse, it must be kept in mind that laser light, while usually thought of as pure monochromatic light on a gross scale, actually exhibits a small wavelength spread about its nominal monochromatic wavelength value. All of the components of the wavelength spread carry energy. This small wavelength spread is the basis for the pulse expansion and compression of the present approach. Based upon this small wavelength spread, the present approach allows temporal broadening and temporal compression of the laser pulse by factors of several thousand. For example, a temporal broadening of a laser pulse from 50 femtoseconds to 200 picoseconds is an expansion by a factor of 4000.
The structure described herein is capable of spatial and temporal compression of a long optical pulse, as well as the spatial and temporal broadening of a short optical pulse by the selective introduction of optical path length as a function of wavelength. Very large expansion and compression ratios are possible because of the absence of both monochromatic and polychromatic aberrations. Additionally, the structure provides for spatial separation of, and therefore easy access to, the input and output beams.
Although a particular embodiment of the invention has been described in detail for purposes of illustration, various modifications and enhancements may be made without departing from the spirit and scope of the invention. Accordingly, the invention is not to be limited except as by the appended claims.
Cook, Lacy G., Thornes, Joshua J.
Patent | Priority | Assignee | Title |
11268860, | Jul 24 2020 | Raytheon Company | Radiometric calibration of detector |
11619709, | Apr 20 2020 | Raytheon Company | Optical system to reduce local internal backscatter |
11754680, | Apr 20 2020 | Raytheon Company | Optical system that detects and blocks backscatter |
Patent | Priority | Assignee | Title |
3943457, | Oct 16 1974 | The United States of America as represented by the Secretary of the Navy | Optical pulse compression and shaping system |
4588957, | Jun 09 1982 | International Business Machines Corporation | Optical pulse compression apparatus and method |
4612641, | May 18 1984 | National Research Council of Canada | Infrared pulse compression |
4750809, | May 01 1985 | SPECTRA-PHYSICS LASERS, INC A DE CORPORATION | Pulse compression |
5907436, | Sep 29 1995 | Lawrence Livermore National Security LLC | Multilayer dielectric diffraction gratings |
6795199, | Jul 18 2001 | Method and apparatus for dispersion compensated reflected time-of-flight tomography | |
20030189756, | |||
20060033923, | |||
DE19744302, | |||
WO3055015, |
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